JP4476872B2 - Vacuum cleaner - Google Patents

Description

  The present invention relates to a vacuum cleaner having a self-propelled function in a vacuum cleaner body.

  As a conventional vacuum cleaner of this type, hose tension detection means is provided at the connection between the hose and the main body of the vacuum cleaner, and the hose tension is detected by the user moving forward and away from the main body of the vacuum cleaner or pulling the suction hose. Is detected by the tension detecting means, there is one in which the main body of the cleaner is caused to self-run in the advancing direction of the suction hose (see, for example, Patent Document 1).

  Also, a transmitting device is provided at a position between the hand handle portion and the suction port body, and a signal transmitted from the transmitter device is received by a receiving device provided in the cleaner body, and the hand handle portion is based on the signal. The distance between the main body of the cleaner and the main body of the cleaner is detected, and the main body of the cleaner is controlled so as to keep the distance between the hand handle portion and the main body of the cleaner (see, for example, Patent Document 2).

JP-A-64-86925 (page 3, upper left column, last line to upper right column, 10 lines) JP-A-2-172433 (first page, claims (1))

  However, in the technique of Patent Document 1, since the main body of the cleaner self-propels only after the hose tension is transmitted to the tension detector, the hose tension is always transmitted to the hand immediately before the main body of the cleaner starts self-propelling. For this reason, the degree of reduction of the operation load during the cleaning operation is not sufficient.

  In this regard, according to the technique of Patent Document 2, by appropriately setting the distance between the hand handle and the vacuum cleaner main body, the vacuum cleaner main body can be self-propelled so that the hose tension is not transmitted to the hand. Although it is possible, if an obstacle such as a human body or furniture enters between the transmitting device and the receiving device during cleaning, the distance between the hand handle and the cleaner body cannot be detected, and there is a problem that it falls into an uncontrollable state there were.

  The present invention has been made in view of the above points, and it is possible to stably control the cleaner main body so that the cleaning operation can be always performed comfortably, and the electric load that can reduce the operation load on the user. The purpose is to provide a vacuum cleaner.

  The vacuum cleaner according to the present invention includes an electric blower and a vacuum cleaner body having a dust collection chamber communicating with the electric blower, and a hose communicating with the dust collection chamber by connecting to a connection port established in the vacuum cleaner body. A pipe communicating with the tip side of the hose, a suction port connected to the tip of the pipe, a traveling wheel that movably supports the cleaner body, a drive unit that drives the traveling wheel, and a hose and a pipe The positional relationship and the drive control value of the drive unit for running control of the cleaner body so that the distance between the suction port body and the cleaner body is a preset distance relationship at the time of the positional relationship. The storage section that stores the control table set in association with each other and the positional relationship between the hose and the pipe between the predetermined part of the hose and the predetermined part of the pipe. Depending on the distance A control unit that determines the drive control value for the drive unit based on the detected positional relationship detection unit, the detection result of the positional relationship detection unit, and the control table of the storage unit, and controls the drive unit based on the drive control value It is equipped with.

  According to this invention, the positional relationship between the hose and the pipe is detected by the angle formed by the predetermined portion of the hose and the predetermined portion of the pipe or the distance between the predetermined portion of the hose and the predetermined portion of the pipe, and the detection result; Since the drive control value for the drive unit is determined based on the control table of the storage unit, and the drive unit is controlled based on the drive control value, the travel control of the cleaner body is performed. The inconvenience that the detection cannot be performed can be prevented, and the vacuum cleaner main body can be stably controlled so that the cleaning operation can always be performed comfortably. Therefore, it is possible to reliably reduce the operation load on the user.

Embodiment 1 FIG.
1-4 is a figure which shows the vacuum cleaner of Embodiment 1 of this invention.
As shown in FIG. 1, the vacuum cleaner is connected to a vacuum cleaner main body 1 having a built-in dust collecting chamber communicating with the electric blower and the electric blower, and a connection port 1 a opened on the front surface of the vacuum cleaner main body 1. A hose 4 communicating with the dust collecting chamber, a handle portion 5 provided on the tip side of the hose 4, a pipe 6 connected to the tip side of the handle portion 5, and a suction port 7 connected to the tip of the pipe 6 The air containing the dust sucked in from the suction port body 7 is an air path inside the pipe 6, a first rotation connection portion 8, which will be described later, the hose 4, and the second rotation connection portion 20. And is sucked into the dust collection chamber. The pipe 6 is configured to be separable near the tip of the handle portion 5 and is configured to be extendable and contractable by the pipe length adjusting means 10. In addition, a pipe attachment / detachment detection unit 17 that detects separation near the tip of the handle unit 5 is provided in the pipe, and is connected to a control unit, which will be described later, by a lead wire (not shown) through the outer periphery of the hose 4. Yes. The handle portion 5 is provided with a power supply operation portion 5a having a power switch (not shown) for turning on and off the electric blower and the like (as with the pipe attachment / detachment detection portion 17), a conductor ( (Not shown) and connected to a control unit described later.

  An auxiliary front wheel 29 (see FIG. 3) having a horizontal rotation shaft is provided in front of the bottom surface of the vacuum cleaner body 1 in a caster that can be rotated in the horizontal direction. The left rear wheel 2 and the right rear wheel 3 (see FIG. 11 to be described later) are provided symmetrically as traveling wheels that movably support the cleaner body 1. The auxiliary front wheel 29, the left rear wheel 2 and the right rear wheel 3 allow the cleaner body 1 to move in any direction on the surface to be cleaned, and the auxiliary front wheel 29 changes the traveling direction of the cleaner body 1. The direction can be changed continuously.

  On the handle portion 5 side of the hose 4, the hose 4 and the pipe 6 are rotatably connected around a vertical axis 8 a (see FIG. 3) perpendicular to a plane including the axis of the hose 4 and the axis of the pipe 6. A first pivot connection 8 is provided. The first rotation connection portion 8 is provided in an air path bending portion 37 as a connection portion that connects the hose 4 and the pipe 6. The first rotation connection portion 8 detects the positional relationship between the hose 4 and the pipe 6 by detecting the rotation angle of the first rotation connection portion 8, and based on the detection result, the suction port body A hose rotation angle detection unit 15 (see FIG. 11 described later) is provided as a positional relationship detection unit that detects the distance between the main body 7 and the cleaner body 1. Specifically, the hose rotation angle detection unit 15 is configured by, for example, a rotary potentiometer. A specific configuration of the first rotation connecting portion 8 will be described in detail with reference to FIGS.

  On the cleaner body 1 side of the hose 4, there is provided a second rotation connection portion 20 that connects the hose 4 to the cleaner body 1 so as to be rotatable in a plane direction parallel to the cleaning surface. The second rotation connection unit 20 detects the rotation angle of the second rotation connection unit 20, thereby detecting the direction of the hose 4 with respect to the cleaner body 1. (See FIG. 11 described later). Specifically, the hose lead-out direction detection unit 16 is configured by, for example, a rotary potentiometer. A specific configuration of the second rotation connecting portion 20 will be described in detail with reference to FIGS.

5-7 is a figure which shows an example of a structure of a 1st rotation connection part.
The first rotation connection portion 8 includes a cover portion 9 including a left cover 9a and a right cover 9b, a shutter portion 10, and a cylindrical hose connection portion 11. The shutter unit 10 includes a large shutter 10a, a middle shutter 10b, and a small shutter 10c from the cover unit 9 side. The shutters 10a, 10b, and 10c are on the upper end side of the hose connection unit 11. Is connected to a cylindrical cylindrical shaft portion 12 that protrudes from the outer periphery of the cover portion 9 so as to be rotatable in a direction in which the cover portion 9 can be accommodated. Further, the cover portion 9, the large shutter 10a, the middle shutter 10b, the small shutter 10c, and the hose connecting portion 11 are connected by sequentially hooking the hook portions 10aa, 10ba, 10ca, and 11a. Then, when the hose connection portion 11 rotates about the cylindrical shaft portion 12, the shutter portion 10 operates in a direction in which the shutter portion 10 is housed in the cover portion 9 or pulled out from the cover portion 9 in conjunction with the rotation operation. It has become.

  Further, as shown in FIG. 7, a distance detecting rotary potentiometer 15 as a hose rotation angle detector 15 is disposed in a portion of the left cover 9a facing the left end surface 12a of the cylindrical shaft portion 12. . The distance detecting rotary potentiometer 15 is fitted to a shaft portion 13 that extends from the left end surface 12 a of the cylindrical shaft portion 12 in the axial direction of the cylindrical shaft portion 12. A detection signal of the rotary potentiometer (hose rotation angle detection unit) 15 is input to a control unit described later via a lead wire (not shown) embedded in the outer periphery of the hose 4.

  In the first rotation connection portion 8 having such a configuration, when the user performs the operation of holding the handle portion 5 and moving the suction port body 7, the hose connection portion 11 is centered on the cylindrical shaft portion 12 in FIG. 5. It rotates in the direction of arrow A. Then, the tip of the hose connection portion 11 is housed in the order of the small shutter 10c, the middle shutter 10b, and the large shutter 10a, and finally the entire shutter 10 is housed inside the cover portion 9. On the other hand, when the user grips the handle portion 5 and performs the operation of pulling the suction port body 7, the hose connection portion 11 rotates in the direction of arrow B in the drawing with the cylindrical shaft portion 12 as an axis. Then, the small shutter 10c, the middle shutter 10b, and the large shutter 10a that are engaged with each other by the hooking portions 10aa, 10ba, 10ca, and 11a are developed in this order and are pulled out from the cover portion 9. FIG. 6 shows a state where it is fully developed.

8-10 is a figure which shows an example of a structure of a 2nd rotation connection part.
The second rotation connection part 20 is formed integrally with the cover part 21 formed in half by the upper cover 21a and the lower cover 21b, and the cover part 21, and is formed by the upper cylinder part 22a and the lower cylinder part 22b. It is comprised from the cylindrical cleaner main body side connection part 22 and the cylindrical hose side connection part 23 which were formed in half. The cover portion 21 has a substantially cylindrical shape with the upper and lower surfaces closed, and a rectangular opening portion 21c is formed in the circumferential direction on the circumferential surface portion. The hose side connection portion 23 includes a cylindrical portion 23a connected to the hose 4 and a guide portion 23b extending outward from the end surface of the cylindrical portion 23a in an arc shape. The cylindrical portion 23a is slidably fitted in a guide groove (not shown) provided on the cover portion 21 and is connected to the cover portion 21 in a state where the cylindrical portion 23a protrudes from an opening portion 21c provided in the cover portion 21.

  Further, a shutter 24 is provided in the cover portion 21 to slidably contact the inner peripheral surface of the cover portion 21 and close the opening portion 21c. The shutter 24 has a configuration in which a strip-like plate-like member is curved so as to be in sliding contact with the peripheral surface portion of the cover portion 21, and is provided at both ends of the tip portion of the guide portion 23 b of the hose side connection portion 23. A hooking portion 24a is formed to be hooked by the locking portion 23c. When the hose side connection portion 23 is rotated by the hook portion 24a, the shutter 24 is moved in conjunction with the rotation. Further, the shutter 24 is formed with an opening 24b for communicating the flow path between the cleaner main body side connecting portion 22 and the inside of the cover portion 21.

  Further, as shown in FIG. 10, a rotary potentiometer 16 as a hose lead-out direction detection unit 16 is disposed on the lower cover 21 b, and the bearing of the rotary potentiometer 16 includes a cleaner main body side connection unit 22. The shaft 22c provided on the bottom surface is press-fitted. The detection signal of the rotary potentiometer (hose lead-out direction detection unit) 16 is input to the control unit 30 via a conducting wire (not shown) embedded in the outer periphery of the hose 4.

FIG. 11 is a schematic diagram showing the path of the control signal in the first embodiment of the present invention.
The control unit 30 is a part that controls the entire electric vacuum cleaner, and receives signals from the power supply operation unit 5a, the hose rotation angle detection unit 15, the hose lead-out direction detection unit 16, and the pipe attachment / detachment detection unit 17, and an input signal It is comprised so that the process according to may be performed. A control program including a processing program for performing the processing and various data are stored in a memory 31 provided in the control unit 30.

  The control unit 30 obtains the distance between the suction port body 7 and the cleaner body 1 based on the detection signal from the hose rotation angle detection unit 15, and the distance between the suction port body 7 and the cleaner body 1. Is controlled to be constant or within a predetermined range (depending on the setting), the left drive motor 32 and the right drive motor 33 are driven and controlled via the motor driver 34, respectively. The travel control is performed. Here, the distance between the suction port body 7 and the cleaner body 1 is determined for the purpose of reducing the load on the user accompanying the movement of the suction port body 7, and specifically, the hose tension is set to the user. Is determined as the distance that cannot be transmitted.

  Moreover, the control part 30 judges the hose derivation | leading-out direction, ie, the advancing direction of the cleaner main body 1, based on the detection signal from the hose derivation | leading-out direction detection part 16, and the cleaner main body 1 carries out self-propelled in the direction. The left drive motor 32 and the right drive motor 33 are controlled. That is, the control unit 30 controls the left drive motor 32 and the right drive motor 33 according to the position of the suction port body 7 with respect to the cleaner body 1. Such motor control is performed based on a control table as shown in FIG. 12 described later, and this control table is created in advance and stored in the memory 31.

12 is a diagram showing a specific example of the control table, and FIGS. 13 and 14 are explanatory diagrams of the control table of FIG.
In the control table, when the rotation angle θ of the first rotation connection portion 8, the rotation angle φ of the second rotation connection portion 20, and each rotation angle are detected, the suction port body 7 is detected. The drive speed as drive control values for the left drive motor 32 and the right drive motor 33 for running control of the cleaner body 1 such that the distance between the cleaner body 1 and the cleaner body 1 has a preset distance relationship. (Speed level) is set. A0 in the figure is the direction in which the hose 4 is led out when the hose 4 is closest to the pipe 6. A <b> 1 to A <b> 5 are the lead-out directions of the hose 4 when the first rotation connection portion 8 is rotated in accordance with the change in the distance between the hose 4 and the pipe 6. θ1 to θ5 are rotation angles of the first rotation connection portion 8 in the respective hose lead-out directions A1 to A5 with reference to the state of A0. D0 indicates the direction of derivation at the limit of turning the hose 4 to the left. D1 to D5 indicate the direction of derivation of the hose 4 from the cleaner body 1 in the left-right direction accompanying the rotation of the second rotation connection part 20, and φ1 to φ7 are the second direction with respect to the derivation direction D0. This is the rotation angle of the rotation connection unit 20.

  In the control table, these rotation angles θ1 to θ5, φ1 to φ7 are set as thresholds for determining the self-running control operation of the cleaner body 1, and for each of a plurality of ranges specified by each threshold, The speed levels of the left drive motor 32 and the right drive motor 33 are set. This control table determines the traveling speed and the operation of the cleaner body 1 (forward, reverse, left turn, right turn, straight drive). The sign + (no sign) at the speed level indicates normal rotation of the motor, and-indicates reverse rotation of the motor.

  Specifically, according to the control table, when the detection angle θ is (θ <θ2) and the detection angle φ is (φ <φ3), the cleaner body 1 is turned to the left and the detection angle θ is (θ <θ2). ), When the detection angle φ is (φ3 ≦ φ <φ4), the cleaner body 1 is moved straight forward, and when the detection angle θ is (θ <θ2) and the detection angle φ is (φ4 ≦ φ <φ7) The main body 1 is set to turn right.

  When the detection angle θ is (θ2 ≦ θ <θ3) and the detection angle φ is (φ <φ3), the vehicle is turned to the left at the current position, the detection angle θ is (θ2 ≦ θ <θ3), and the detection angle φ is (φ3 It is set to stop when ≦ φ <φ4) and to turn right at the current position when the detection angle θ is (θ2 ≦ θ <θ3) and the detection angle φ is (φ4 ≦ φ <φ7).

  Further, when the detection angle θ is (θ3 ≦ θ <θ5) and the detection angle φ is (φ <φ3), the cleaner body 1 is turned leftward, and the detection angle θ is (θ3 ≦ θ <θ5). When φ is (φ3 ≦ φ <φ4), the vacuum cleaner main body 1 is moved straight forward, and when the detection angle θ is (θ3 ≦ θ <θ5) and the detection angle φ is (φ4 ≦ φ <φ7), it is rotated clockwise. It is set to rotate.

  Moreover, it sets so that turning to the left side or the right side of the vacuum cleaner main body 1 may become quick, so that the derivation direction D of the hose 4 swings to the left side or the right side and approaches D0 or D7. Specifically, the rotational speed difference between the left rear wheel 2 and the right rear wheel 3 is set large.

Next, the operation of the present embodiment will be described.
When the vacuum cleaner body 1 is operated and the suction port body 7 is moved back and forth while holding the handle portion 5 in the hand, the first rotary connection portion 8 and the second rotary connection portion 20 are moved along with the operation. Rotate. The rotation angle by this rotation is detected by a rotary potentiometer (hose rotation angle detection unit) 15 for detecting a distance and a rotary potentiometer (hose extraction direction detection unit) 16 for detecting a derivation direction, respectively, and sequentially controlled. Is output to the unit 30. Based on the detection signals from the rotary potentiometer (hose rotation angle detector) 15 and the rotary potentiometer for direction detection (hose lead-out direction detector) 16 and the control table, the controller 30 controls the left rear wheel 2. And the speed level of each of the right rear wheel 3 is determined. The left driving motor 32 and the right driving motor 33 are driven and controlled via the motor driver 34 based on the motor output value corresponding to the speed level. Thereby, the vacuum cleaner main body 1 self-propels so that the distance between the suction inlet body 7 may be kept constant or within a predetermined range.

This will be specifically described below.
FIG. 15 is an explanatory diagram of a specific example of the operation of the first embodiment, and shows the state of the cleaning operation. Here, the handle portion 5 is held in the hand and the suction port body 7 is moved straight forward from the state where the suction port body 7 is in the basic position (FIG. 15 (a)) (FIG. 15 (b)), and then is moved backward in the straight traveling state ( Next, consider a case where an operation of moving forward (FIG. 15 (d)) is performed so as to turn leftward (FIG. 15 (c)). Hereinafter, the traveling control operation of the cleaner body 1 in each of (a) to (d) will be described in order.

(A) Now, when the lead-out direction A of the hose 4 is located between A2 and A3 and the right-and-left lead-out direction D of the hose 4 is located between D3 and D4, the hose rotation angle detection unit 15 , Θ2 ≦ θ <θ3 is detected, and the hose lead-out direction detector 16 detects an angle φ in the range of φ3 ≦ φ <φ4. The control unit 30 that has received the detection result indicates that the speed levels of the left rear wheel 2 and the right rear wheel 3 are both “0” based on the received detection results and the control table (see FIG. 12). recognize. Therefore, the control unit 30 outputs no drive signal to the left drive motor 32 and the right drive motor 33. Thereby, the cleaner body 1 is stopped.

(B) And when the suction port body 7 is moved straight forward, the lead-out direction A of the hose 4 is located between A3 and A4, and the left-right lead-out direction D of the hose 4 is located between D3 and D4. The rotation angle detector 15 detects an angle θ in the range of θ3 ≦ θ <θ4, and the hose lead-out direction detector 16 detects an angle φ in the range of φ3 ≦ φ <φ4. The control unit 30 that has received the detection result recognizes that the speed levels of the left rear wheel 2 and the right rear wheel 3 are both “3” based on the received detection results, the angle, and the control table. The left drive motor 32 and the right drive motor 33 are driven and controlled in accordance with the level. Thereby, the cleaner main body 1 moves forward in a straight traveling state and approaches the suction port body 7 side. Here, when the straight forward movement of the suction port body 7 is performed more quickly than in the above case, and the detection angle θ on the hose rotation angle detection unit 15 side is in the range of θ4 ≦ θ <θ5, the control unit 30 Recognizes that the speed levels of both the left rear wheel 2 and the right rear wheel 3 are “4”, and causes the cleaner body 1 to move forward straight ahead more quickly than in the above case.

(C) And when the suction port body 7 is moved straight backward, the lead-out direction A of the hose 4 is located between A1 and A2, and the left-right lead-out direction D of the hose 4 is located between D3 and D4. The rotation angle detector 15 detects an angle θ in the range of θ1 ≦ θ <θ2, and the hose lead-out direction detector 16 detects an angle φ in the range of φ3 ≦ φ <φ4. The control unit 30 that has received the detection result recognizes that the speed levels of the left rear wheel 2 and the right rear wheel 3 are both “−3” based on the received detection results and the control table. The left drive motor 32 and the right drive motor 33 are driven and controlled in accordance with the level. As a result, the cleaner main body 1 moves straight backward and leaves the suction port body 7. Here, if the suction port body 7 is rapidly moved straight backward as compared with the above case, and the detection angle θ on the hose rotation angle detection unit 15 side is in the range of θ <θ1, the control unit 30 Recognizing that the speed levels of the left rear wheel 2 and the right rear wheel 3 are both “−4”, the vacuum cleaner main body 1 is caused to move straight forward backward compared to the above case.

(D) Subsequently, the suction port body 7 is advanced so as to turn leftward, the lead-out direction A of the hose 4 is located between A3 and A4, and the left-right lead-out direction D of the hose 4 is D2. When positioned between D3, the hose rotation angle detector 15 detects an angle θ in the range of θ3 ≦ θ <θ4, and the hose lead-out direction detector 16 detects an angle φ in the range of φ2 ≦ φ <φ3. . The control unit 30 that has received the detection result indicates that the speed level of the left rear wheel 2 is “2” and the speed level of the right rear wheel 3 is “3” based on the received detection results and the control table. And the left side driving motor 32 and the right side driving motor 33 are driven and controlled in accordance with the level. As a result, the cleaner body 1 turns to the left while moving forward.

  Here, when the lead-out direction A of the hose 4 is A5 or more, that is, when the pipe 6 approaches the floor surface in parallel (when the positional relationship between the pipe 6 and the hose 4 is substantially in a straight line), The moving angle detector 15 detects an angle θ in the range of θ5 ≦ θ. The control unit 30 that has received the detection result recognizes that the speed levels of the left rear wheel 2 and the right rear wheel 3 are both “0” based on the received detection result and the control table, and is used for driving the left side. The motor 32 and the right drive motor 33 are not driven. That is, the cleaner body 1 is stopped. By doing in this way, the cleaner main body 1 is prevented from traveling unnecessarily when cleaning under furniture or the like.

  Moreover, the control part 30 becomes a structure which stops the self-propelled function of the cleaner body 1 when the pipe 6 is in the separated state. That is, when pipe removal is detected by the pipe attachment / detachment detection unit 17 at the start or operation of the cleaner body 1, the left drive motor 32 and the right drive are driven regardless of the position of the suction port 7 with respect to the cleaner body 1. The driving of the motor 33 is stopped, and the travel of the cleaner body 1 is stopped. Thereby, when the pipe 6 is isolate | separated, it can prevent that the cleaner main body 1 performs operation | movement which a user does not intend.

  As described above, according to the first embodiment, the hose 4 and the pipe 6 are rotatably connected around the vertical axis 8a perpendicular to the plane including the axis of the hose 4 and the axis of the pipe 6. 1 is provided, and the distance between the suction port body 7 and the cleaner body 1 is detected by the hose rotation angle detection section 15 provided in the first rotation connection section 8, and the detection is performed. Since the travel control of the cleaner body 1 is performed based on the signal, it is possible to prevent the inconvenience that the distance cannot be detected as in the prior art. Further, the cleaner main body 1 can be quickly followed to an accurate position in accordance with the movement of the handle portion 5, and a comfortable cleaning operation can always be performed. Therefore, it is possible to reliably reduce the operation load on the user.

  In addition, since the second rotary connection portion 20 is connected to the hose 4, the vacuum cleaner body 1 can be reduced in size compared to the case where the second rotary connection portion 20 is provided in the cleaner body 1, and the space is narrow. It becomes easy to store.

Embodiment 2. FIG.
In the second embodiment, the length of the hose 4 is set so that the hose 4 does not get in the way of the user's feet.

  FIG. 16 is an explanatory diagram showing a moving state of each part of the human body and the handle when the user grips the handle while the user is stationary and moves the arm back and forth. Note that the state shown in FIG. 16 particularly shows a state in which the hose 4 is set to an optimum length (required minimum length).

  In FIG. 16, L is the height of the user, and θ is the angle formed by the center axis of the user's body and the arm when the arm is moved to the front side and the rear side. Generally, the angle (θ) of the user's arm when cleaning is in a range of about ± 45 ° at the maximum (the arrow direction is the positive direction). H is the grip height of the handle portion 5 at the position where the user moves the arm to an angle of 45 °, and is calculated by the following equation (1) using the finger node height (A) and the shoulder peak height (B). it can. H1 is represented by (B−A) cos 45 ° because the length of the arm is B−A.

      H = B- (BA) cos 45 ° (1)

Further, S is a moving distance of the handle portion 5 when the arm portion is moved back and forth by 45 ° with the handle portion 5 and can be calculated by the following equation (2).
S = 2 (B-A) sin45 ° (2)

  FIGS. 17 and 18 are graphs analyzed from the data of “Japanese anthropometric data 1992-1994” published by the Research Center for Human Life Engineering, and L, A, and B in the figure are L, A in FIG. , B respectively. This data is the average of the height and finger joint height (A) and shoulder peak height (B) of 10667 males and 5835 females aged 20 to 59 years, and the data belonging to 90% excluding the upper and lower 5% each It was created with reference to the maximum and minimum values.

  FIG. 19 is a graph showing the relationship of the grip height (H) of the handle portion 5 to the height (L) when the angle (θ) between the central axis of the body and the arm is 45 °, and FIG. It is the graph which showed the relationship of the movement distance (S) of the handle | steering-wheel part 5 with respect to height (L).

  When the position of the suction port body 7 is set with respect to the cleaner body 1 so that the cleaner body 1 is always located close to the user and travel control is performed, depending on the length of the hose 4, the hose 4 may be slackened to the user's feet. Become. Therefore, usability is improved by setting the hose 4 to a minimum length that does not cause tension in the hose 4 within the range of reciprocation of the handle portion 5. In setting the length of the hose 4, the purpose is to deal with most users who use a vacuum cleaner, and a person with a height of 1780 mm or less, including 95% of men, is determined.

It can be seen that the grip height (H) of the handle portion 5 of a person having a height of 1780 mm is 997 mm from FIG. 19, and the moving distance (S) of the handle portion 5 is 924 mm from FIG. Here, as shown in FIG. 16, the distance (X) between the handle portion 5 and the rotation center P1 of the first rotation connection portion 8 is 120 mm, and the connection height (I) of the hose 4 to the cleaner body 1 is set. When the minimum length (Z) of the hose 4 in the case of 90 mm, finger node height (A) is 806 mm, and shoulder peak height (B) is 1459 mm, it is 912 mm from the equation (3). Here, the length Z of the hose 4 is a length from the rotation center P1 of the first rotation connection portion 8 to the bending start position of the hose 4 (position where the hose side connection portion 23 can be bent) P2.
Z = (H2 ² + D1 ² ) ^1/2
= [(HI-X) ² + (S / 2) ² ] ^1/2
= [{B− (BA) cos 45 ° −I−X} ² + {(B−A) sin 45 °} ² ] ^1/2
.... (3)

  However, since the actual hose 4 bends while being bent, tension is generated in the hose 4 by the reciprocating operation of the handle portion 5 at the minimum length (Z) of the hose 4. Therefore, the value obtained by the following equation (4) is used.

Z1 = Z + C (4)
Where C: minimum bend radius of hose 4

  In this way, by giving the hose length a margin about the minimum bending radius of the hose 4, the generation of tension can be substantially suppressed. Therefore, taking a PVC hose with an outer diameter of about 45 mm as an example, the minimum bending radius is about 80 mm, so the length of the hose 4 is set to 992 mm by adding this to the minimum length (Z) 912 mm. Even if a user with a height of 1780 mm reciprocates the handle part 5 back and forth in a stationary state, the hose 4 does not generate tension and does not get in the way of the feet, so that a user-friendly vacuum cleaner is constructed. Can do.

  Accordingly, during the actual cleaning operation, the horizontal distance (D) between the handle portion 5 and the bending start position of the hose 4 (the position where the hose side connecting portion 23 can be bent) P2 is set to the moving distance (S If the self-running of the vacuum cleaner body 1 is controlled to be equal to or less than the distance obtained by adding 542 mm, which is a length of about 462 mm which is half the length of) and a margin of the minimum bending radius of 80 mm, An easy-to-use vacuum cleaner that does not generate tension and does not get in the way of the feet can be configured. The horizontal distance (D) varies depending on the minimum bending radius of the hose 4 and is not limited to the calculated value 542 mm, but is appropriately changed according to the minimum bending radius of the hose 4.

  When the length of the hose 4 is set as described above, the slack of the hose 4 increases when a person with a short height uses it. However, since the slack is alleviated by arranging the position of the cleaner body 1 rearward, the operation is not significantly impaired.

  As described above, by configuring the hose 4 to the minimum necessary length, the hose 4 is slackened and is difficult to contact the floor surface, so that the movement of the hose 4 when the handle portion 5 is moved in the left-right direction is reduced. It is transmitted to the hose lead-out direction detector 16 without delay, and the lead-out direction of the hose 4 can be accurately detected. Thereby, traveling control can be performed accurately.

  Further, since the hose 4 can be prevented from slackening and coming into contact with the floor surface, fraud detection by the hose rotation angle detection unit 15 due to the contact of the hose 4 and the pipe 6 or the hose 4 is bent in an unintended direction. Incorrect detection by the hose lead-out direction detection unit 16 when the hose is swung can be prevented.

  In each of the above embodiments, the self-running function always works based on the detection signals of the hose rotation angle detection unit 15 and the hose lead-out direction detection unit 16 except when the pipe 6 is separated. As described above, an on / off switch for turning on and off the drive motors 32 and 33 may be provided in the power supply operation unit 5a of the handle unit 5 so that the self-running function can be stopped as necessary. Thereby, when cleaning high places or low places, or when the vacuum cleaner body 1 is routed or carried before and after cleaning, the drive motors 30 and 34 can be stopped.

  In each of the above embodiments, the positional relationship between the hose 4 and the pipe 6 is grasped based on the rotation angle of the hose rotation angle detection unit 15 that detects the rotation angle of the first rotation connection unit 8. The distance between the suction port body 7 and the cleaner body 1 is set in advance based on a control table in which the relationship between the positional relationship and the speed levels of the left drive motor 32 and the right drive motor 33 is set. The travel of the cleaner body 1 is controlled so that the distance relationship is the same, but the positional relationship between the hose 4 and the pipe 6 is detected based on the rotation angle of the hose rotation angle detector 15. However, the detection may be performed based on the angle formed by the predetermined portion of the hose 4 and the predetermined portion of the pipe 6 or the distance between the predetermined portion of the hose 4 and the predetermined portion of the pipe 6. In this case as well, a corresponding control table may be created in advance and traveling control may be performed according to the control table.

  The predetermined portion of the hose 4 is specifically a portion between the connecting portion of the hose 4 and the pipe 6 to the center of the length of the hose 4, and the predetermined portion of the pipe 6 is The portion between the connection portion of the hose 4 and the pipe 6 and the center of the length of the pipe 6 is used. In this way, by detecting the angle or distance between the predetermined portions on the connection portion side of the hose 4 and the pipe 6, in the cleaning operation with the handle portion 5 provided at the connection portion, A situation in which an obstacle such as a human body or furniture enters between the parts can be eliminated, and a conventional inconvenience that the detection operation cannot be performed can be prevented.

  Specifically, as for detecting the distance between the predetermined portions, as shown in FIGS. 21 to 23, a magnetic sensor 41a and an ultrasonic sensor 42 used in combination with a slide type potentiometer 40 and a magnet 41b, respectively. Can be used. FIGS. 21 to 23 show examples in which these sensors are applied to the first rotation connection unit 8, but they are applied to the second rotation connection unit 20 and the third rotation connection unit 35. You may do it. In addition, the same sensor may be used for all of the rotational connection portions, or may be used in combination as appropriate.

It is a perspective view of the whole vacuum cleaner which shows Embodiment 1 of this invention. It is a whole perspective view at the time of separating the cleaner body which shows Embodiment 1 of this invention. It is a side view of the whole vacuum cleaner which shows Embodiment 1 of this invention. It is a perspective view of the hose rotation angle detection part vicinity which shows Embodiment 1 of this invention. It is a perspective view which shows the structural example of the 1st rotation connection part in Embodiment 1 of this invention. It is a cross-sectional view which shows the structural example of the 1st rotation connection part in Embodiment 1 of this invention. It is a front sectional view showing an example of composition of the 1st rotation connection part in Embodiment 1 of this invention. It is a perspective view which shows the structural example of the 2nd rotation connection part in Embodiment 1 of this invention. It is an upper section showing an example of composition of the 2nd rotation connection part in Embodiment 1 of this invention. It is a cross-sectional view which shows the structural example of the 2nd rotation connection part in Embodiment 1 of this invention. It is a schematic diagram which shows the path | route of the control signal in Embodiment 1 of this invention. It is a figure which shows a specific example of a control table. It is explanatory drawing (the 1) of the control table of FIG. It is explanatory drawing (the 2) of the control table of FIG. It is the figure which showed the mode of cleaning operation | movement. It is explanatory drawing which showed the movement state of each part of a human body and a handle | steering_body part at the time of grasping | ascertaining a handle | steering-wheel part in the state where the user was still and moving an arm back and forth. It is a graph which shows the relationship between a user's height and phalanx height. It is a graph which shows the relationship between a user's height and shoulder height. It is a graph which shows the relationship between a user's height and the grip height of a handle part. It is a graph which shows the relationship between a user's height and the movement distance of a handle part. It is FIG. (1) which shows the other structural example of the sensor for detecting a rotation angle. It is FIG. (2) which shows the other structural example of the sensor for detecting a rotation angle. It is FIG. (The 3) which shows the other structural example of the sensor for detecting a rotation angle.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Vacuum cleaner main body, 1a connection port, 2 left rear wheel, 3 right rear wheel, 4 hose, 5 handle part, 6 pipe, 7 suction port body, 8 1st rotation connection part, 8a vertical axis, 15 hose turn Movement angle detection unit, 16 hose lead-out direction detection unit, 17 pipe attachment / detachment detection unit, 20 second rotation connection unit, 30 control unit, 32 left side drive motor, 33 right side drive motor, 35 third rotation connection Part, 40 slide type potentiometer, 41a magnetic sensor, 42 ultrasonic sensor.

Claims (11)

A vacuum cleaner body including a dust collecting chamber communicating with the electric blower and the electric blower;
A hose communicating with the dust collection chamber by connecting to a connection port established in the vacuum cleaner body;
A pipe communicating with the tip side of the hose;
A suction port connected to the tip of the pipe;
A running wheel that movably supports the vacuum cleaner body;
A drive unit for driving the traveling wheel;
For controlling the travel of the cleaner body such that the positional relationship between the hose and the pipe and the distance between the suction port body and the vacuum cleaner body at the time of the positional relationship is a preset distance relationship. A storage unit for storing in advance a control table set in association with the drive control value of the drive unit;
A positional relationship detection unit that detects a positional relationship between the hose and the pipe based on an angle formed by a predetermined portion of the hose and a predetermined portion of the pipe or a distance between the predetermined portion of the hose and the predetermined portion of the pipe. When,
A control unit that determines a drive control value for the drive unit based on a detection result of the positional relationship detection unit and the control table of the storage unit, and controls the drive unit based on the drive control value; A vacuum cleaner characterized by that.   A first rotation connecting portion that rotatably connects the hose and the pipe about a vertical axis perpendicular to a plane including the axis of the hose and the axis of the pipe; The electric vacuum cleaner according to claim 1, wherein the positional relationship detection unit is provided in the rotary connection unit. A second rotation connecting portion for connecting the hose to the cleaner body so as to be rotatable in a plane direction parallel to the cleaning surface;
A hose derivation direction detection unit that detects a derivation direction of the hose with respect to the cleaner body by detecting a rotation angle of the second rotation connection unit is provided in the second rotation connection unit,
The control table of the storage unit further sets the drive control value of the drive unit in association with the detection result of the hose derivation direction detection unit,
3. The electric vacuum cleaner according to claim 1, wherein the control unit determines a drive control value for the drive unit in consideration of a detection result of the hose lead-out direction detection unit.   4. The electric vacuum cleaner according to claim 3, wherein the second rotating connection portion is connected to the hose.   The control table has a positional relation range obtained by dividing an angle formed by a predetermined portion of the hose and a predetermined portion of the pipe or a distance between the predetermined portion of the hose and the predetermined portion of the pipe into a plurality of ranges, and 5. The drive control value of the drive unit is set for each hose lead-out direction range obtained by dividing the lead-out direction of the hose with respect to the cleaner body into a plurality of ranges. Electric vacuum cleaner.   In the control table, a drive control value corresponding to the positional relationship range from a predetermined state to a state in which the hose and the pipe are substantially in a straight line is set to 0. Item 6. A vacuum cleaner according to item 5.   The pipe is configured to be separable in the middle, and includes a detection unit that detects a separation / connection state of the pipe, and the control unit does not drive the driving unit when separation is detected by the detection unit. The electric vacuum cleaner according to any one of claims 1 to 6, wherein   8. The preset distance relationship is to keep a distance between the suction port body and the cleaner body constant or within a predetermined range. Electric vacuum cleaner. The vacuum cleaner according to any one of claims 1 to 8, wherein a length Z1 of the hose is set to a value obtained from the following equation.
Z1 = [{B− (BA) cos 45 ° −I−X} ² + {(BA) sin45 °} ² ] ^1/2 + C
Here, I: connection height of the vacuum cleaner body of the hose, X: distance to the rotation center of the handle portion and the first rotation connection portion, A: the user whose height is the largest among the target users Finger joint point height, B: shoulder height of the highest user among the target users, C: minimum bend radius of the hose   Instead of controlling the drive unit so that the distance between the suction port body and the cleaner body maintains a preset distance relationship, the control unit, instead of controlling the drive unit and the bending start position of the hose The horizontal distance (D) between the hose and the minimum bend radius (hose) of the hose is half the length of the moving distance (S) of the handle when the handle is held and the arm angle is moved back and forth to 45 °. The electric vacuum cleaner according to claim 9, wherein the driving unit is controlled to be equal to or less than a distance obtained by adding C). The vacuum cleaner according to any one of claims 1 to 10, wherein the positional relationship detection unit is configured by any one of a rotary potentiometer, a slide potentiometer, a magnetic sensor, and an ultrasonic sensor.

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